Article: Modelling and energy efficiency analysis of a hybrid pump-controlled asymmetric (single-rod) cylinder drive system Journal: International Journal of Hydromechatronics (IJHM) 2020 Vol.3 No.1 pp.1 - 25 Abstract: A conventional valve-controlled cylinder drive system is not energy efficient, and a pump-controlled cylinder system can be unstable in some particular conditions. For drive systems not requiring fast response, a hybrid pump-controlled system, that combines the advantages of both valve and pump-controlled systems, is proposed. As nonlinear behaviours are inevitable in most asymmetric cylinder drive systems, the hybrid pump-controlled system also suffers from such problems, and extra nonlinear behaviours are identified, for example, stall when the cylinder change its direction of motion. A simulation model of the hybrid pump-controlled asymmetric cylinder drive system is developed and used to investigate the system's simulation behaviours which are analysed and compared with the experimental test results. The energy efficiency of the hybrid pump-controlled system is compared with a comparable valve-controlled hydraulic system with the same hydraulic cylinder sizing. The outcome is to demonstrate the advantage of the hybrid pump-controlled system in energy-saving aspect, and the efficiency of the hybrid system is up to five times more than a conventional hydraulic system. Suggestions are given to improve the performance and stability of the hybrid pump-controlled system. Inderscience Publishers - linking academia, business and industry through research

Title: Modelling and energy efficiency analysis of a hybrid pump-controlled asymmetric (single-rod) cylinder drive system

Authors: Huankun Wang; Paul G. Leaney

Addresses: Loughborough University, Epinal Way, Loughborough, Leicestershire, LE11 3TU, UK ' Loughborough University, Epinal Way, Loughborough, Leicestershire, LE11 3TU, UK

Abstract: A conventional valve-controlled cylinder drive system is not energy efficient, and a pump-controlled cylinder system can be unstable in some particular conditions. For drive systems not requiring fast response, a hybrid pump-controlled system, that combines the advantages of both valve and pump-controlled systems, is proposed. As nonlinear behaviours are inevitable in most asymmetric cylinder drive systems, the hybrid pump-controlled system also suffers from such problems, and extra nonlinear behaviours are identified, for example, stall when the cylinder change its direction of motion. A simulation model of the hybrid pump-controlled asymmetric cylinder drive system is developed and used to investigate the system's simulation behaviours which are analysed and compared with the experimental test results. The energy efficiency of the hybrid pump-controlled system is compared with a comparable valve-controlled hydraulic system with the same hydraulic cylinder sizing. The outcome is to demonstrate the advantage of the hybrid pump-controlled system in energy-saving aspect, and the efficiency of the hybrid system is up to five times more than a conventional hydraulic system. Suggestions are given to improve the performance and stability of the hybrid pump-controlled system.

Keywords: asymmetric cylinder; hybrid pump-controlled; valve-controlled; energy efficiency; nonlinear behaviour; simulation.

DOI: 10.1504/IJHM.2020.105501

International Journal of Hydromechatronics, 2020 Vol.3 No.1, pp.1 - 25

Received: 15 Aug 2019
Accepted: 15 Sep 2019
Published online: 02 Mar 2020 *

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Title: Modelling and energy efficiency analysis of a hybrid pump-controlled asymmetric (single-rod) cylinder drive system

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